EP3203629A1 - Method for secure deactivation of a drive system - Google Patents

Abstract

The invention relates to a method for safely switching off a drive system (2) having a converter (6) connected to a supply network (12) with a DC intermediate circuit (16) for providing a DC link voltage (U ZK) for a number of electric motors (4) a motor power converter (8) connected to the intermediate circuit (16), and a switched control unit (28), wherein the control unit (28) reliably interrupts the intermediate circuit (16) on the basis of a switch-off signal (A, A 1, A 2).

Description

The invention relates to a method for safely switching off a drive system. It further relates to a switchable by this method drive system. The term "safe" is understood to mean the fulfillment of a safety function, in particular the so-called safe torque-off function.

In the field of drive technology with electric motors as electrical machines, in particular with synchronous and asynchronous motors, safety-related functions are required to avoid injuries due to unwanted or unexpected rotations of the drives reliable and reliable. An important safety function in this context is a safe torque-off (STO) called safe hold of the drive by this is safely separated from its power supply to effect a stop after triggering the safety function and to achieve its rest position reliable.

Such a drive system usually comprises a converter connected to a supply network, in particular a frequency converter, with a DC intermediate circuit for providing a DC link voltage for a number of electric motors. The electric motors are in this case connected as three-phase motors by means of a controlled current or inverter to the intermediate circuit voltage, in particular in a parallel circuit. In this case, the (motor) power converters typically comprise a number of semiconductor switches which, as a controlled bridge circuit, convert the intermediate circuit voltage, for example into a three-phase motor voltage.

From the DE 103 07 999 B4 a control device for a self-commutated power converter with a safety function is known in which operationally or in the event of a fault, the control signals of the semiconductor switches of the bridge circuit are switched off safely. As a result, the motor power converter can not generate a three-phase current for the electric motor, so that the electric motor comes to a standstill. Also, the supply voltage of the semiconductor switch could be switched off in the converter side.

In such a drive system, the safety function is thus integrated decentrally in the individual motor power converters. As a result, such drive systems are subject to high production costs and a comparatively high installation or wiring effort.

The invention has for its object to provide a suitable method for safely switching off a drive system. In particular, a reliable and centrally controlled safety function should be made possible. Furthermore, a drive system which can be switched off safely according to such a method should be specified.

With regard to the method, the stated object with the features of claim 1 and with respect to the drive system with the features of claim 4 is achieved according to the invention. Advantageous embodiments and further developments are the subject of the respective subclaims.

The method according to the invention serves for a safe shutdown of a drive system. In this case, the drive system comprises a converter connected to a supply network with a DC intermediate circuit, which is also referred to below as an intermediate circuit, for providing an intermediate circuit voltage for a number of electric motors, for example synchronous or asynchronous motors. The converter is preferably designed as a frequency converter and has, on the one hand, a network-side rectifier for feeding and generating the intermediate circuit voltage and a number of motor-side motor power converters corresponding to the number of electric motors for conversion the DC link voltage in a three-phase current or in a multi-phase motor voltage. In particular, each motor is assigned a motor converter as an inverter and connected by means of this to the DC link.

In the intermediate circuit, a connecting and disconnecting circuit is further connected, the method according to a shutdown signal of a control unit interrupts the intermediate circuit safely. Due to the interruption of the DC link, the DC link voltage is switched off, so that the connected motor DC converters do not generate any three-phase current for the electric motor. As a result, a central shutdown of the DC link voltage - and thus of the connected electric motors - in the course of a safety function, in particular in the course of a signal represented by the shutdown STO functionality, simple and inexpensive.

The shutdown of the electric motors is not decentralized, in contrast to the prior art, but centrally by means of a centrally controlled safety function, for example by means of a designed as a bus controller control unit. In other words, the shutdown of the electric motors using a centrally-connected control unit, whereby a mounting and wiring cost of the drive system is reduced. This further transfers advantageous to the manufacturing cost of such a drive system.

For this purpose, the drive system according to the invention expediently has a connecting and disconnecting circuit which is interconnected in the intermediate circuit and which is signal-technically connected to the control unit and is suitable and arranged to reliably interrupt the intermediate circuit as a function of the switch-off signal.

The motor power converters each have an inverter circuit, in particular a bridge circuit controlled by a motor control or motor control for converting the intermediate circuit voltage into the motor voltage. The bridge circuit preferably comprises a number of semiconductor switches, in particular insulated gate bipolar transistors (IGBT), which be controlled by means of a pulse width modulated drive signal of the motor control. In contrast to the prior art, in the course of the safety function, not the supply voltage or the drive signal of the motor-commutator-internal semiconductor switch is interrupted, but the intermediate circuit connected in front of it. As a result, the inverter circuits do not generate any three-phase currents for the respective electric motor.

Functionally, the intermediate circuit has a plus path and a minus path, which are contacted accordingly to the plus or minus pole of the network-side rectifier. For this purpose, the electric motors or their associated motor power converters are connected in a parallel connection between the positive path and the negative path, and thus supplied with the intermediate circuit voltage.

The control unit is embodied, for example, as a bus controller for a central drive control of the electric motors, and as such, in terms of signaling, is contacted by means of a bus line with the motor controllers of the motor power converters. Suitably, the control unit is also arranged to trigger a circuit breaker, which is preferably connected in front of the rectifier in the supply network. As a result, the entire drive system can be safely separated from the supply network in case of need or error.

The control unit is generally - program and / or circuitry - set up to carry out the inventive method described above. The control unit is thus concretely configured to control switching elements of the connection and disconnection circuit, that is to say to open or close in response to the disconnection signal. The switch-off signal is triggered in this case, for example, by one of the motor controls coupled by means of the bus line, which detects an error case by means of an engine-side sensor, or by an external, manually actuatable emergency stop switch. The shutdown signal is preferably triggered as a result of a triggering or activation of a safety function, in particular the STO function.

The control unit is formed at least in the core by a microcontroller with a processor and a data memory, in which the functionality for performing the method according to the invention in the form of operating software (firmware) is implemented by programming, so that the method - optionally in interaction with a user - at Execution of the operating software in the microcontroller is performed automatically.

The control unit is alternatively formed in a possible embodiment within the scope of the invention but also by programmable electronic components, such as an application-specific integrated circuit (ASIC), in which the functionality for performing the method according to the invention is implemented by circuitry means. In particular, in such an embodiment, for example, it is conceivable that the control unit and the connection and disconnection circuit are designed as a common ASIC.

In a particularly advantageous embodiment of the method from a safety point of view, it is provided that the DC link is separated by two channels. In other words, two switchable Abschaltkanäle the control unit in the intermediate circuit, in particular in the course of the connection and disconnection circuit, interconnected. According to the invention, each shutdown channel is assigned at least one triggerable semiconductor switch of the connection and disconnection circuit for interrupting the intermediate circuit, that is, for disconnecting the intermediate circuit voltage. As a result, a redundant interruption is realized. This means that even in the case of an error of one of the shutdown channels, or one of the associated semiconductor switches, a reliable shutdown of the drive system is ensured.

The two separate shutdown channels are, for example, connected in series together in the plus path or in the minus path of the DC link. Alternatively, it is also conceivable that in each case a shutdown channel in the positive path and a shutdown channel are provided in the negative path.

In an advantageous embodiment, at least one controllable first semiconductor switch in the plus path and / or in the minus path of the intermediate circuit is switched off as a result of the switch-off signal by means of the control unit. As a result, a particularly easy-to-control and cost-effective interruption of the intermediate circuit is made possible.

To monitor the shutdown in this case is preferably provided that each drive or each motor control detects its respective applied DC link voltage. The acquired voltage values are sent to the control unit via the bus line. The control unit is suitable and configured to evaluate the received voltage values and to check whether the disconnection or interruption of the intermediate circuit was successful. In the event of an error, which means that the interruption was unsuccessful, the control unit triggers the circuit breaker connected in the supply network so that the drive system is safely disconnected from the infeed.

In a preferred embodiment, in each of which a semiconductor switch is connected in the plus path and in the minus path, it is possible by the detection of the intermediate circuit voltage to check whether one of the semiconductor switches has not opened. Since one of the number of connected electric motors corresponding number of voltage values are transmitted to the control unit, a faulty measurement is essentially excluded.

Suitably, each drive or each motor control is assigned a drive number, which is transmitted with the respective voltage value. This ensures on the safety unit side that the voltage values have been sent by different motor controllers. The control unit expediently has a counting device which records a value proportional to the number of voltage values and monitors it continuously during operation. If this value does not change, it is detected that there is no connection to a drive and the switch-off signal is triggered.

In one possible embodiment, in addition to or as an alternative to the second semiconductor switch, at least one switching element of the connection and disconnection circuit is provided as a circuit breaker. The at least one circuit breaker is arranged in the positive path and / or in the negative path, in particular in a series connection with the first semiconductor switch. This allows electromechanical and galvanic isolation of the DC link. The circuit breaker is designed, for example, as an electronic, mechanical or mechatronic switch or as a relay.

Preferably, the first semiconductor switch is first switched in the course of an interruption of the intermediate circuit and then the circuit breaker. When connecting the DC link, first the circuit breaker and only then the first semiconductor switch is closed. Through this switching sequence of the circuit breaker always de-energized, which is advantageous to the life of the switch contacts transmits. The circuit breaker has a positively driven feedback contact, which is signal-technically coupled to the control unit. As a result, the control unit detects whether it has been switched off safely. Through the circuit breaker within the DC link no additional circuit breaker in the supply network is necessary.

In an expedient embodiment, the connection and disconnection circuit has a connection path, in particular between the positive path and the negative path of the intermediate circuit. In the connection path, a discharge resistor and a connected in series third semiconductor switch, for example in the form of a transistor, connected. In the normal operation of the drive system, the third semiconductor switch is opened in the connection path, whereby the discharge resistor is effectively released from the connection and disconnection circuit. In the course of a shutdown, in which the intermediate circuit is interrupted, the third semiconductor switch is closed, so that the plus path and the minus path are connected by the connection path. As a result, a direct current flows through the discharge resistor, which discharges the intermediate circuit capacitors of the motor converter and thus reduces the intermediate circuit voltage. By the integrated discharge resistor thus a short reaction time of the STO function is ensured.

Another or further aspect of the invention provides that the connection and disconnection circuit has at least one evaluation circuit coupled to the control unit. The evaluation circuit serves additionally or alternatively to the motor controls to a detection of a voltage value in the DC bus. The voltage value detected by the evaluation circuit is compared with a reference voltage, wherein, depending on the comparison, an output or control signal triggering the switch-off signal is sent to the control unit.

In an advantageous embodiment, in each case such an evaluation circuit is assigned to the first and the second semiconductor switch. This means that preferably each one evaluation circuit is provided for monitoring the switching state of the respective semiconductor switch. For this purpose, the respective evaluation circuit is connected in front of and behind the corresponding semiconductor switch in the positive path or in the negative path. In this case, the evaluation circuit is in each case connected between a network-side and a motor-side connection of the respective semiconductor switch, which means in particular in each case on the collector and emitter side, connected in the intermediate circuit. In other words, the first evaluation circuit detects a voltage signal at the first semiconductor switch, and the second evaluation circuit detects a voltage signal at the second semiconductor switch. In one possible embodiment, the evaluation circuits and the respective semiconductor switch are designed as a common electronic component.

By detecting the voltage across the semiconductor switches, a reliable detection of the shutdown or the switching state of the connection and disconnection circuit is made possible. If, for example, the detected voltage value is lower than the reference voltage, then the associated semiconductor switch is deemed to be closed, and a corresponding output signal is applied to the Control unit shipped. The reference voltage is tapped for example at a voltage divider.

In an expedient development, the evaluation circuits each have resistor chains formed by protective impedance resistors for detecting the respective voltage value. A resistor chain is to be understood here in particular as a series connection of protective impedance resistors. The voltage value is detected, for example, by means of an operational amplifier (OP), for which purpose a first resistor chain between the line-side terminal of the semiconductor switch and the first input of the OP and a second resistor chain between the motor-side terminal of the semiconductor switch and the second input of the OP is connected. The output of the OP is then compared by means of a comparator with the reference voltage.

In one possible further development form, each evaluation circuit in this case has two such circuits which are connected in series directly one behind the other in the intermediate circuit, wherein the signal of the second comparator is inverted, for example by means of an inverter. In other words, the second circuit always supplies the inverted signal of the first circuit in normal operation. This means that each evaluation circuit generates two output signals for the control unit. By evaluating the two pairs of output signals, the control unit is suitable and configured to reliably and reliably detect the switching state of the connection and disconnection circuit.

In an expedient embodiment, the protective impedance resistors of the resistor chains are designed in particular as metal-electrode-leadless-faces (MELF) resistors. MELF resistors are always high impedance in the event of a fault, so that in the event of a short circuit within the resistor chain it is ensured that the control unit reliably detects the fault by means of the evaluation circuit.

In one conceivable embodiment, the connection and disconnection circuit is integrated in a housing of the network-side rectifier. In other words, the safety function is integrated in the supply of the DC link. Alternatively, the connection and disconnection circuit is arranged, for example with the control unit together in a separate housing, which is interconnected in the intermediate circuit.

Fig. 1

ein Antriebssystem mit einem Umrichter mit einem Gleichstromzwischenkreis und mit einer Anzahl von Elektromotoren sowie mit einer Verbindungs- und Trennschaltung,

Fig. 2

eine Ausführungsform der Verbindungs- und Trennschaltung mit einem Verbindungspfad,

Fig. 3

eine zweite Ausführungsform der Verbindungs- und Trennschaltung,

Fig. 4

eine Ausführungsform der Verbindungs- und Trennschaltung mit zwei Auswerteschaltungen, und

Fig. 5

die Auswerteschaltungen.

Embodiments of the invention will be explained in more detail with reference to a drawing. Therein show in schematic block diagram representations:

Fig. 1

a drive system with a converter with a DC intermediate circuit and with a number of electric motors and with a connection and disconnection circuit,

Fig. 2

an embodiment of the connection and disconnection circuit with a connection path,

Fig. 3

a second embodiment of the connection and disconnection circuit,

Fig. 4

an embodiment of the connection and disconnection circuit with two evaluation circuits, and

Fig. 5

the evaluation circuits.

Corresponding parts and sizes are always provided with the same reference numerals in all figures.

The Fig. 1 shows a schematic representation of a drive system 2 with a number of electric motors 4, which are operated by means of a respective inverter 6. Exemplary are in the Fig. 1 four electric motors 4, wherein two of the electric motors 4 are provided with reference numerals by way of example. The electric motors 4 are designed as three-phase synchronous or asynchronous motors and, as such, each have an associated motor converter 8 and a motor controller 10 controlling this.

The inverters 6 are each connected as a frequency converter to a three-phase supply network 12. For this purpose, the respective inverter 6 comprises a Mains-side rectifier 14 as a supply unit and the motor controller 10 and in particular designed as an inverter motor-side motor converter 8. Between the rectifier 14 and the motor converters 8 a DC intermediate circuit 16 is formed, which is also referred to below as the intermediate circuit 16. The intermediate circuit 16 has functionally a plus path 18 which is contacted to the positive terminal of the rectifier 14, and a negative path 20, which is contacted in accordance with the negative pole of the rectifier 14.

During operation of the drive system 2, an intermediate circuit voltage U _{ZK is applied} as a supply voltage for the connected electric motors 4 between the positive pole and the negative pole of the rectifier 14. The electric motors 4 are each contacted by means of their motor power converter 8 between the plus path 18 and the negative path 20 to the intermediate circuit 16, wherein the electric motors 4 are thus in particular coupled in a parallel circuit to each other to the intermediate circuit 16. The motor power converters 8 each have a bridge circuit for converting the DC voltage U _ZK into a three-phase three-phase current for operation of the respective electric motor 4.

Directly behind the rectifier 14, a connecting and disconnecting circuit 22 of the inverter 6 is connected in the intermediate circuit 16. In other words, each connected electric motor 4 comprises a converter 6 comprising the rectifier 14, the connecting and disconnecting circuit 22 and in each case an associated motor power converter 8 with motor control 10. The connection and disconnection circuit 22 includes in the in Fig. 1 The circuit arrangement 24 is signal technically coupled to a control unit 28, and suitable and set up in response to a switch-off signal A of the control unit 28 to interrupt the intermediate circuit 16 such that the connected electric motors 4 are switched off safely. The term "safe" in this context, in particular the fulfillment of a safety function, in particular the safe torque-off function to understand. Preferably, the connection and separation circuit 22 and the control unit 28 integrated in a housing of the rectifier 14.

The circuit arrangement 24 is executed in terms of circuitry with a redundant shutdown for interrupting the intermediate circuit 16. This means that a total of two shutdown channels are provided for switching off or interrupting the intermediate circuit 16, which are each provided with an operable switching element S ₁ and S ₂ . In the embodiments of the FIGS. 1, 2 and 4 is the switching element S ₁ in the positive path 18 and the switching elements S ₂ in the negative path 20 connected.

The control unit 28 is preferably provided in terms of circuitry and / or programming technology to check the functionality and / or functional reliability of the connection and disconnection circuit 22 or its circuit arrangement 24.

The connection path 26 comprises a discharge resistor 30 and a switching element S ₃ connected in series therewith, for example in the form of a transistor. During normal operation of the drive system 2, the switching element S _{3 of} the connection path 26 is opened so that no electric current flows via the discharge resistor 30.

In the positive path 18, a charging resistor 32 is connected to a switching element S ₄ connected in parallel therebetween between the switching element S ₁ and the connection of the connection path 26. The motor power converters 8 have (intermediate) capacitors not shown in more detail, which are charged via the charging resistor 32 when the drive system 2 starts up. During such a charging process, the switching element S _{4 is} preferably open, so that the supply or operating current flows only through the charging resistor 32. In normal operation, the switching element S _{4 is} closed, so that a low-resistance connection between the rectifier 14 and the connected electric motors 4 is realized.

In the course of a safe shutdown process, in which the intermediate circuit 16 is interrupted by the circuit 24, the switching element S _{3 is} closed, so that the positive path 18 and the negative path 20 are connected to each other via the connection path 26. As a result, a direct current flows through the discharge resistor 30, which thus discharges intermediate circuit capacitors of the motor converter 8. By discharging the intermediate circuit _voltage U _{ZK is} reduced, so that the electric motors 4 are brought to a safe halt.

In the in Fig. 2 illustrated embodiment, the switching elements S ₁ , S ₂ , S ₃ and S _{4 are designed} as a semiconductor switch, in particular as transistors with parallel-connected freewheeling diodes.

The circuit arrangement 24 comprises four drivers 34, 36, 38 and 40, which generate in operation in each case a clocked signal for driving the semiconductor switches S ₁ , S ₂ , S ₃ and S ₄ . Due to the clocking, it is possible for the drive signals of the semiconductor switches S ₁ , S ₂ , S ₃ and S ₄ to realize a Potentialtennung means of a transformer. The drivers 34, 36, 38 and 40 are controlled by a microcontroller or programmable logic 42 signal-coupled to the control unit 28. To interrupt the intermediate circuit 16, the control unit 28 sends a switch-off signal A ₁ for opening the semiconductor switch S ₁ and a switch-off signal A ₂ for opening the semiconductor switch S ₂ . Alternatively, however, it is also conceivable that by using suitable outputs of the control unit 28, the shutdown signals A ₁ and A _{2 are} interconnected in such a way that only a shutdown signal A between the control unit 28 and the circuit 24 is shipped. At and in particular within the circuit arrangement 24, however, the switch-off signal A is preferably divided again into the switch-off signals A ₁ and A ₂ .

Upon receipt of the switch-off signal A ₁ or A ₂ , the driver 34 or 36 switches off, so that in the course of a pulse lock no drive signals for the semiconductor switches S ₁ and S _{2 are} generated. At the same time the driver 38 is turned on by a switching signal A ₃ , so that the semiconductor switch S _{3 is} closed in particular clocked, and the DC link voltage U _ZK discharges by means of the discharge resistor 30 via the connection path 26.

To check the switching states is the switching elements S ₁ and S ₂ - as in particular in the Fig. 4 can be seen - in each case an evaluation circuit 44a, 44b connected in parallel. The evaluation circuits 44a and 44b detect a voltage signal U ₁ or U ₂ between the respective collector and emitter-side terminals of the semiconductor switches S ₁ and S ₂ . The evaluation circuits 44a and 44b respectively send an evaluation signal B or C to the logic 42 and / or the control unit 28 as a function of the detected voltage signals U ₁ and U ₂ .

The motor controls 10 of the motor converter 8 are contacted by a signal technically to a common bus line 46. A designed as a contactor circuit breaker 48 is connected in front of the rectifier 14 in the supply network 12, and is triggered by the control unit 28 in case of need or error. Upon tripping of the circuit breaker 48, the inverter 6, and thus the drive system 2, is electrically isolated from the supply network 12.

The control unit 28 is programmed and / or circuitally configured to control the circuit arrangement 24 of the connection and disconnection circuit 22. The switch-off signal A, or the respective (individual) switch-off signal A ₁ , A _{2 of} the corresponding switching elements S ₁ and S ₂ is triggered in particular as a result of triggering or activation of a safety function, in particular the STO function. By thus causing interruption of the intermediate circuit 16, the intermediate circuit voltage U _{ZK is} switched off and discharged, so that the connected motor converter 8 generate no three-phase current for the electric motor 4 and an immediate stop of the electric motors 4 is effected.

That in the Fig. 3 illustrated embodiment shows an electromechanical design of the two-channel interruption. In this embodiment, the two-channel interruption of the circuit 24 is realized by the series-connected switching elements S ₁ and S ₂ within the positive path 18.

The switching element S ₁ is in this embodiment as an electronically actuated circuit breaker and the switching element S ₂ as a semiconductor switch, in particular as an IGBT executed. By the circuit breaker S ₁ , a galvanic isolation of the intermediate circuit 16 is possible. In the course of an interruption of the intermediate circuit 16 of the semiconductor switch S ₂ is first switched off directly by the shutdown signal A ₂ , and then the circuit breaker S ₁ is actuated by the shutdown signal A ₁ . When connecting the intermediate circuit 16, first the circuit breaker S _{1 is} closed and then the half-circuit switch S ₂ . The circuit breaker S ₁ has a positively driven feedback contact, by means of which a feedback signal R is sent to the transmission of the switching state to the control unit 28.

In the Fig. 4 a two-channel shutdown by means of two semiconductor switches S ₁ and S _{2 is} shown, wherein the semiconductor switches S ₁ and S ₂ as in the Fig. 1 and in the Fig. 2 in the plus path 18 on the one hand and in the negative path 20 on the other hand are connected. In this embodiment, the interruption of the intermediate circuit 16 is purely electronic, wherein the connecting and disconnecting circuit 22 in the embodiment of Fig. 4 additionally represents the two evaluation circuits 44a and 44b, the structure of which based on the Fig. 5 will be explained in more detail below.

In the Fig. 5 During evaluation, the evaluation circuits 44a and 44b, which are shown in more detail, detect the switching state of the respective associated semiconductor switch S ₁ or S ₂ during operation. For this purpose, the evaluation circuits 44a and 44b each have two resistance chains 52a, 52b, 52c, 52d formed by protective impedance resistors 50. The protective impedance resistors 50, which are designed in particular as MELF resistors, are disclosed in US Pat Fig. 5 merely exemplified with reference numerals. Although the protective impedance resistors 50 are given the same reference numerals, the individual protective impedance resistors 50 may have different electrical resistance values from each other. Preferably, however, the resistance chains 52a, 52b, 52c, 52d formed thereby each have the same total resistance.

The resistor chain 52a is connected between a network-side terminal 54 of the semiconductor switch S ₁ and a first input of an operational amplifier 56a, and the resistor chain 52b is connected between a motor-side terminal 58 of the semiconductor switch S ₁ and a second input of the operational amplifier 56a. Accordingly, the resistor chain 52c is connected between a line-side terminal 60 of the semiconductor switch S ₂ and a first input of an operational amplifier 56b and the resistor chain 52b is connected between a motor-side terminal 62 of the semiconductor switch S ₂ and a second input of the operational amplifier 56b.

The outputs of the operational amplifiers 56a, 56b are each connected to a first input of an associated comparator 64a, 64b. At the respective other input of the comparator 64a or 64b, a reference voltage U _{ref is} applied, which is tapped at a respective voltage divider 66a, 66b. Like in the FIG. 5 comparatively clearly seen, the voltage divider 66b of the evaluation circuit 44b is inverted to the comparator 64b connected. This means that the comparator 64b generates an inverted output signal compared to the comparator 64a.

The output or evaluation signal B of the comparator 64a is sent to the control unit 28. The corresponding output signal of the comparator 64b is sent as the evaluation signal C to the control unit 28.

Based on the two output signals B and C, the control unit 28 is set up to reliably detect the switching state of the connection and disconnection circuit 22.

The invention is not limited to the embodiments described above. On the contrary, other variants of the invention can be derived by the person skilled in the art without departing from the subject matter of the invention. In particular, all the individual features described in connection with the exemplary embodiments can also be combined with one another in other ways, without departing from the subject matter of the invention.

For detecting the charging or discharging state of the intermediate circuit 16, it is additionally conceivable, for example, that further evaluation circuits are connected in the circuit arrangement 24. Thus, in one possible embodiment, for example, a further evaluation circuit for monitoring the switching state of the semiconductor switch S _{4 is} provided. For this purpose, the corresponding evaluation circuit between the collector-side terminal 68 on the one hand and the emitter-side terminal 70 of the semiconductor switch S ₄ on the other hand connected.

Furthermore, it is additionally or alternatively also conceivable to provide an evaluation circuit for the semiconductor switch S _{3 of} the connection path 26. The corresponding evaluation circuit is interconnected, for example, between the terminal 70 and the terminal 62. As a result, two additional evaluation signals are generated during operation in addition to the evaluation signals B and C. Due to the four evaluation signals, a particularly reliable monitoring of the connection and disconnection circuit 22 is possible with the control unit 28.

In a further conceivable embodiment, the circuit arrangement 24 is executed in terms of circuitry with a redundant dual-channel shutdown for interrupting the intermediate circuit 16. This means that a total of four shutdown channels are provided for switching off or interrupting the intermediate circuit 16. In other words, two switching elements in each case are connected in series in the plus path 18 or in the minus path 20, wherein a switching element in the plus path 18 and a switching element in the minus path 20 form a common switching element pair, which cooperates in accordance with the switching elements S ₁ and S ₂ described above ,

This makes it possible, for example during operation of the drive system 2 to test the shutdown paths regularly for errors, since the probability of failure of the switching elements involved is not zero. For this purpose, the functionality of the switching elements at each change of the drive signals A ₁ and A ₂ checked on the basis of the evaluation signals B and C. This ensures a particularly reliable and reliable interruption of the intermediate circuit 16, since on the one hand the intermediate circuit 16 is interrupted by means of two separate switching elements two channels and on the other hand, this two-channel interruption is redundant.

LIST OF REFERENCE NUMBERS

2

drive system

4

electric motor

6

inverter

8th

Motor converter

10

motor control

12

supply network

14

rectifier

16

DC / DC link

18

plus path

20

minus path

22

Connecting and disconnecting circuit

24

circuitry

26

connection path

28

control unit

30

discharge

32

load resistance

34, 36, 38, 40

driver

42

Microcontroller / logic

44a, 44b

evaluation

46

bus line

48

breaker

50

Schutzimpendanzwiderstand

52a, 52b, 52c, 52d

resistor chain

54

connection

56a, 56b

operational amplifiers

58, 60, 62

connection

64a, 64b

comparator

66a, 66b

voltage divider

68, 70

connection

U _ZK

Intermediate circuit voltage

S ₁ , S ₂ , S ₃ , S ₄

Switching element / semiconductor switch / circuit breaker

A, A ₁ , A ₂

shutdown signal

A ₃

switching signal

U ₁ , U ₂

voltage signal

U _ref

reference voltage

R

Feedback signal

B, C

Evaluation signal / output signal

Claims (12)

Method for safely switching off a drive system (2) with a converter (6) connected to a supply network (12) with a DC intermediate circuit (16) for providing a DC link voltage (U _ZK ) for a number of electric motors (4) with one each to the DC link (16) connected motor power converter (8), and with a in the intermediate circuit (16) connected separating circuit (22) for the safe interruption of the intermediate circuit (16) by a control unit (28) a shutdown signal (A, A ₁ , A ₂ ) is supplied. Method according to claim 1,
characterized,
that the intermediate circuit (16) is separated by two channels. Method according to claim 1 or 2,
characterized,
in that at least one controllable semiconductor switch (S ₁ , S ₂ ) in the positive path (18) and / or in the negative path (20) of the intermediate circuit (16) is switched off by means of the control unit (28) as a result of the switch-off signal (A, A ₁ , A ₂ ) , Drive system (2) with a connected to a supply network (12) inverter (6) with a DC intermediate circuit (16) for providing an intermediate circuit voltage (U _ZK ) for a number of electric motors (4) each having a to the DC link (16) connected motor converter (8), and with a connecting and disconnecting circuit (22) which is connected in the intermediate circuit (16) and which is technically connected to a control unit (28) which is adapted to operate the intermediate circuit (16) on the basis of a switch-off signal (A, A ₁ , A ₂ ) to be safely interrupted by means of the connection and disconnection circuit (22). Drive system (2) according to claim 4,
characterized,
that the connecting and disconnecting circuit (22) has at least two semicon terschalter (S ₁ , S ₂ ) for interrupting the intermediate circuit (16). Drive system (2) according to claim 4 or 5,
characterized,
that a first semiconductor switch (S ₁₎ of the connecting and separating circuit (22) is connected in the positive path (18) of the intermediate circuit (16), and that a second semiconductor switch (S ₂₎ of the connecting and separating circuit (22) in the negative path (20 ) of the intermediate circuit (16) is connected. Drive system (2) according to one of claims 4 to 6,
characterized,
in that the connection and disconnection circuit (22) has a connection path (26), in particular between the positive path (18) and the negative path (20) of the intermediate circuit (16), in which a discharge resistor (30) and a third connected in series thereto Semiconductor switch (S ₃ ) are interconnected. Drive system (2) according to one of claims 4 to 7,
characterized,
in that the connection and disconnection circuit (22) has at least one evaluation circuit (44a, 44b) coupled to the control unit (28) for detecting a voltage value (U ₁ , U ₂ ) in the intermediate circuit (16) which depends on a comparison of the respective voltage value (U ₁ , U ₂ ) with a reference voltage (U _ref ) a the shutdown signal (A, A ₁ , A ₂ ) triggering output signal (B, C) to the control unit (28) shipped. Drive system (2) according to claim 8,
characterized,
in that in each case one evaluation circuit (44a, 44b) is associated with the first semiconductor switch (S ₁ ) and the second semiconductor switch (S ₂ ). Drive system (2) according to claim 9,
characterized,
in that the evaluation circuit (44a, 44b) has resistance chains (52a, 52b, 52c, 52d) formed by protective impedance resistors (50) for detecting the respective voltage value (U ₁ , U ₂ ). Drive system (2) according to claim 10,
characterized,
in particular, that the protective impedance resistors (50) are MELF resistors. Drive system (2) according to one of claims 4 to 11,
characterized,
in that the connection and disconnection circuit (22) is integrated in a housing of a network-side rectifier (14) of the converter (6).

Images